Multifunctional PECVD layers: Dopant source, passivation, and optics

J. Seiffe, F. Pillath, D. Trogus, A. Brand, C. Savio, M. Hofmann, J. Rentsch
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Abstract

In this study, the feasibility of creating one dielectric layer system acting simultaneously as antireflection coating, phosphorous doping source, masking against metal plating, and surface passivation is presented. Moreover, a similar layer stack is described, which behaves as rear-side surface passivation, boron dopant source, and internal reflection mirror. The optical characteristics of these layers are especially investigated and optimized for a solar cell's front- and rear-side coating. By consequent use of the multifunctional layers, a totally diffused solar cell with rear-side passivation and local rear contacts can be produced using only one wet chemical bath sequence, one multilayer vacuum step, and one high-temperature process. We present the first proof of concept for such a solar cell production using multifunctional plasma-enhanced chemical vapor deposition layers resulting already in a conversion efficiency of 18.3%.
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多功能PECVD层:掺杂源、钝化和光学
在本研究中,提出了创建一个介质层体系同时作为增透涂层、磷掺杂源、屏蔽金属镀层和表面钝化的可行性。此外,还描述了一种具有后表面钝化、硼掺杂源和内反射镜作用的类似层叠。这些层的光学特性特别研究和优化了太阳能电池的前后侧涂层。通过随后的多功能层的使用,仅使用一个湿化学浴序列、一个多层真空步骤和一个高温工艺就可以生产具有后侧钝化和局部后触点的全扩散太阳能电池。我们提出了使用多功能等离子体增强化学气相沉积层生产这种太阳能电池的第一个概念证明,其转换效率已经达到18.3%。
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